Influence of solvent and water activity on kinetically controlled peptide synthesis.

alpha-Chymotrypsin deposited on Celite was used to catalyse peptide synthesis reactions between N-protected amino acid esters and leucine amide in organic media with low water content. The influence of the solvent and the thermodynamic water activity on the reaction kinetics was studied. The substrate specificity in the reactions was shown to be a combination of the substrate specificity of the enzyme in aqueous media and the influence of the solvents. The magnitude of the solvent effects differed greatly depending on the substrates used. In hydrophobic solvents high reaction rates were observed and the competing hydrolysis of the ester substrate occurred to only a minor extent. Reactions occurred at water activities as low as 0.11, but the rate constants increased with increasing water activity and were about two orders of magnitude higher at the highest water activity tested (0.97).     

How to predict product yield in kinetically controlled enzymatic peptide synthesis

The published theory of kinetically controlled enzymatic peptide synthesis needed experimental verification. We carried out the measurement of the peptide yield and estimation of the key parameters alpha and beta for papain-catalyzed synthesis of Mal-L-Phe-L-Ala-LLeuNH(2) from Mal-L-Phe-L-AlaOMe and L-LeuNH(2). The experimental results demonstrate that this theory adequately describes the real process. (c) 1992 John Wiley & Sons, Inc.     

Solid-phase acyl donor as a substrate pool in kinetically controlled protease-catalysed peptide synthesis

Recently we have demonstrated the advantage of solid- phase substrate pools mainly in equilibrium controlled protease-catalysed peptide syntheses. The extension of this approach to protease-catalysed acyl transfer reactions will be presented. The model reaction was systematically investigated according to both the influence of solid phases present in the system on enzyme activity as well as nucleophile concentration on peptide yield. The key parameter for obtaining high peptide yield via acyl transfer is the ratio between aminolysis and hydrolysis. We combined high nucleophile concentrations with solid-phase acyl donor pools. This approach enabled us to supply ester substrate and nucleophile in equimolar amounts in a high-density media without the addition of any organic solvent. Several multi-functional di- to tetrapeptides were obtained in moderate to high yields. ©1997 European Peptide Society and John Wiley & Sons, Ltd.     

Use of model peptide reactions for the characterization of kinetically controlled ligation

Since the introduction of kinetically controlled ligation (KCL), a chemoselective reaction between a peptide-(α)thioarylester and a Cys-peptide-(α)thioalkylester, KCL has been utilized for the total chemical synthesis of large proteins (i.e., lysozyme and HIV-protease) by providing fully convergent synthetic routes. Although KCL has the potential to become an important chemistry for protein synthesis, the principle of KCL is not fully characterized. In particular, prior work on KCL has focused on the reactivity difference of the two different -(α)thioester forms-alkyl vs aryl. Another equally important feature of KCL, Xaa-Cys ligation sites, has not been investigated. The work reported here describes combinatorial KCL reactions using model peptides to dissect the interplay of the Xaa(1), Xaa(2), -(α)thioarylester, and -(α)thioalkylester. Results from these studies provide fundamental insights into the KCL reaction, and will lead to the optimal synthetic route for the routine chemical synthesis of large target protein molecules.     

The application of papain,ficin and clostripain in kinetically controlled peptide synthesis in frozen aqueous solutions

The capability of the cysteine proteases ficin, papain and clostripain to form peptide bonds in frozen aqueous solutions was investigated. Freezing the reaction mixture resulted in increased peptide yields in kinetically controlled coupling of Bz–Arg–OEt with various amino acid amides and dipeptides. Under these conditions, peptide yields increased up to 70% depending on the enzyme and the amino component used. Enzyme-catalysed peptide syntheses were carried out under optimized reaction conditions (temperature, amino component concentration and pH before freezing) using the condensation of Bz–Arg–OEt and H–Leu–NH₂ as a model reaction.     

Selective synthesis of panthenyl esters by a kinetically controlled enzymatic process

Abstract

Panthenyl esters (panthenyl monoacetate and panthenyl diacetate) were synthesized in high yields (≈100%) by a kinetic reaction control using a commercial immobilized Candida Antarctica lipase B (Novozyme 435) in acetonitrile. The enzyme showed excellent synthetic activity, regioselectivity, and operational stability under the conditions used.     

Kinetic studies of peptide bond formation. Effect of chloramphenicol

There might be an undetermined order in the interaction of the substrates with the ribosomes in the reaction of CACCA-Leu-Ac with puromycin to form Ac-Leu-puromycin and CACCA (fragment reaction). Km 0°=6×10^-4 M for the puromycin · ribosome interaction. Chloramphenicol totally blocks the fragment reaction as a consequence of a single interaction with the ribosome of Kd 0°=2.2×10^-6 M. The inhibition by chloramphenicol of the fragment reaction is mixed competitive for puromycin.     

Bacillus licheniformis protease-catalyzed peptide synthesis via the kinetically controlled approach using the carbamoylmethyl ester as an acyl donor in anhydrous acetonitrile

Summary The couplings ofN-protected amino acid esters with amino acid amides proved to be carried out in anhydrous acetonitrile in the presence ofBacillus licheniformis protease (subtilisin Carlsberg) immobilized on Celite. The maximal peptide yields were obtained with the immobilized enzyme prepared through lyophilization from a pH 10.7 buffer solution. A series of dipeptide syntheses and several segment condensations were achieved generally in high yields by the combined use of the immobilized enzyme prepared from this pH and the carbamoylmethyl ester as the acyl donor.     

Reactivity of the P-site-bound donor in ribosomal peptide-bond formation

The puromycin reaction, catalyzed by the ribosomal peptidyltransferase, has been carried out so as to make the definition of two distinct parameters of this reaction possible. These are (a) the final degree of the reaction which gives the proportion of peptidyl (P)-site binding of the donor and (b) the reactivity of the donor substrate expressed as an apparent rate constant (kobs). This kobs varies with the concentration of puromycin; the maximal value (k3) of the kobs, at saturating concentrations of puromycin, gives the reactivity of the donor independently of the concentrations of both the donor and puromycin. k3 is also a measure of the activity of peptidyltransferase expressed as its catalytic rate constant (kcat). If we assume that the puromycin-reactive donor is bound at the ribosomal P site, we observe the following, depending on the conditions of the experiment: the proportion of P-site binding of the donor substrates AcPhe-tRNA or fMet-tRNA can be the same and close to 100%, while there is a tenfold increase in the reactivity of the donor (k3 = 0.8 min-1 versus 8.3 min-1). On the other hand there are conditions, under which the proportion of P-site binding increases from 30% to 100% while k3 remains low and equal to 0.8 min-1. Using the puromycin reaction it was also found that an increase of Mg2+ from 10 mM to 20 mM reduces the reactivity of the donor and, hence, the activity of peptidyltransferase, provided that this change in Mg2+ occurs during the binding of the donor but not when it occurs during peptide bond formation per se. The fact that the donor substrate may exist in various states of reactivity in this cell-free system raises the possibility that the rate of peptide bond formation may not be uniform during protein synthesis.     

Kinetic controlled synthesis of pH-responsive network alginate

Alginates are of considerable interest in the fields of biotechnology and biomedical engineering. To enable the control of properties generally not possible with the native polymer, we have chemically modified alginate with dialdehyde via acid-catalyzed acetalization. The kinetics of acetalization measured through equilibrium swelling of the networked polymer were found to undergo a zero- and second-order reaction with respect to alginate and dialdehyde, respectively. With the determined rate constant of 19.06 microL x mole(-1) x s(-1) at 40 degrees C and activation energy of 78.58 kJ x mol(-1), a proposed predictive reaction model may be used a priori to select reaction conditions providing specific polymer properties. Gel swelling and average pore size were then able to be controlled between 80-1000-fold and 35-840 nm, respectively, by predictive estimation of reagent concentration and formulation conditions. This semisynthetic but natural polymer is stimuli-responsive exhibiting high water absorbency and may potentially be used as drug delivery vehicle for protein therapeutics.     

Modelling of the enzymatic kinetically controlled synthesis of cephalexin: influence of diffusion limitation

In this study the influence of diffusion limitation on enzymatic kinetically controlled cephalexin synthesis from phenylglycine amide and 7-aminodeacetoxycephalosporinic acid (7-ADCA) was investigated systematically. It was found that if diffusion limitation occurred, both the synthesis/hydrolysis ratio (S/H ratio) and the yield decreased, resulting in lower product and higher by-product concentrations. The effect of pH, enzyme loading, and temperature was investigated, their influence on the course of the reaction was evaluated, and eventually diffusion limitation was minimised. It was found that at pH >or=7 the effect of diffusion limitation was eminent; the difference in S/H ratio and yield between free and immobilised enzyme was considerable. At lower pH, the influence of diffusion limitation was minimal. At low temperature, high yields and S/H ratios were found for all enzymes tested because the hydrolysis reactions were suppressed and the synthesis reaction was hardly influenced by temperature. The enzyme loading influenced the S/H ratio and yield, as expected for diffusion-limited particles. For Assemblase 3750 (the number refers to the degree of enzyme loading), it was proven that both cephalexin synthesis and hydrolysis were diffusion limited. For Assemblase 7500, which carries double the enzyme load of Assemblase 3750, these reactions were also proven to be diffusion limited, together with the binding-step of the substrate phenylglycine amide to the enzyme. For an actual process, the effects of diffusion limitation should preferably be minimised. This can be achieved at low temperature, low pH, and high substrate concentrations. An optimum in S/H ratio and yield was found at pH 7.5 and low temperature, where a relatively low reaction pH can be combined with a relatively high solubility of 7-ADCA. When comparing the different enzymes at these conditions, the free enzyme gave slightly better results than both immobilised biocatalysts, but the effect of diffusion limitation was minimal.     

Enzymatic synthesis of oligosaccharides: product removal during a kinetically controlled reaction

In this article, the enzymatic production of oligosaccharides, which is an example of a kinetically controlled reaction, is studied. The aim is to show that the product yield can be enhanced by continuous removal of oligosaccharides from the reaction mixture. The oligosaccharides were removed by adsorption on activated carbon. The absorption could be described by the multicomponent Langmuir isotherm with different maximum saturation constants for mono-, di-, and trisaccharides. The affinity for trisaccharides was larger (k(tri) = 3.52 l/g) than for di- (k(di) = 0.94 l/g) and monosaccharides (k(mono) = 0.11 l/g). A model combining kinetics, adsorption on activated carbon, and mass transfer in an adsorption column was developed. Model calculations for the batch process with removal showed a yield improvement of 23% compared to the batch process without removal. Experimentally, a yield improvement of 30% was obtained. Model calculations for the continuous process studied did not result in an increase of the yield. The advantages of removal were masked by the negative influence of recirculation and the relative large time between formation and removal. Copyright John Wiley & Sons, Inc.     

Kinetic studies on activation of peptide bond formation by hyaluronic acid.

1. In this study, a cell-free system derived from Escherichia coli has been used in order to examine in detail the effect of hyaluronic acid on peptide bond formation with the aid of puromycin reaction. 2. This reaction is activated by hyaluronic acid. 3. The degree of activation of peptide bond formation depends on the molecular size of hyaluronic acid. 4. The kinetic analysis revealed that the hyaluronic acid acts as a mixed-type nonessential activator. 5. The presence of hyaluronic acid improves about 9-fold the activity status of ternary complex as it can be calculated by k3/k5 ratio.     

Alcalase-catalyzed, kinetically controlled synthesis of a precursor dipeptide of RGDS in organic solvents

The protease-catalyzed, kinetically controlled synthesis of a precursor dipeptide of RGDS, Z-Asp-Ser-NH2 in organic solvents was studied. Alcalase, an industrial alkaline protease, was used to catalyze the synthesis of the target dipeptide in water-organic cosolvents systems with Z-Asp-OMe as the acyl donor and Ser-NH2 as the nucleophile. Acetonitrile was selected as the organic solvent from acetonitrile, ethanol, methanol, DMF, DMSO, ethyl acetate, 2-methyl-2-propanol, and chloroform tested under the experimental conditions. The conditions of the synthesis reaction were optimized by examining the effects of several factors, including water content, temperature, pH, and reaction time on the Z-Asp-Ser-NH2 yields. The optimum conditions are pH 10.0, 35 degrees C, in acetonitrile/Na2CO3-NaHCO3 buffer system (85:15, v/v), 6 h, with a dipeptide yield of 75.5%.     

Bacillus licheniformis protease-catalyzed peptide synthesis via the kinetically controlled approach using the carbamoylmethyl ester as an acyl donor in anhydrous acetonitrile

The couplings of N-protected amino acid esters with amino acid amides proved to be carried out in anhydrous acetonitrile in the presence of Bacillus licheniformis protease (subtilisin Carlsberg) immobilized on Celite. The maximal peptide yields were obtained with the immobilized enzyme prepared through lyophilization from a pH 10.7 buffer solution. A series of dipeptide syntheses and several segment condensations were achieved generally in high yields by the combined use of the immobilized enzyme prepared from this pH and the carbamoylmethyl ester as the acyl donor.     

Kinetic analysis of chemotactic peptide receptor modulation

The dynamics of the chemotactic peptide receptor on rabbit peritoneal polymorphonuclear leucocytes were followed using the tritiated peptide N-formylnorleucylleucylphenylalanine (FNLLP). We have used a kinetic analysis to examine the possible interrelationships between receptor loss (down-regulation), receptor-mediated peptide uptake, and receptor recycling. We have previously demonstrated that cells incubated with FNLLP show a dose-dependent reduction in the number of receptors available on the surface. This receptor down-regulation is complete within 20 min and then the number of receptors available for binding remains at a plateau level. Peptide continues to be taken up in a receptor-mediated manner even after down-regulation is complete. If peptide is removed, receptor recovery occurs and does not require protein synthesis. In these studies we have investigated the kinetics of these processes. On the basis of this analysis, we propose that the plateau receptor level is a steady-state in which receptor internalization and return occur continuously. We demonstrate that the rate of receptor-mediated peptide uptake is approximately equal to the rate of receptor recovery measured after peptide removal. In addition, the rate of receptor recovery is proportional to the number of receptors missing from the surface, suggesting receptor recycling may be occurring.     

Kinetic parameters governing the formation of eIF-2.methionyl-tRNAi complexes in protein synthesis

Published data have been analysed to determine the rate constants governing the exchange of GDP in the complex of the eukaryotic protein synthesis initiation factor eIF-2 with GDP, catalysed by eIF-2B. The interaction of eIF-2B with eIF-2.GDP appears to include a very high 'on' rate constant of up to 4 x 10(8) M-1 sec-1 - a value very similar to that found by others for the interaction of the bacterial elongation factors Tu and Ts. Assuming a substituted enzyme mechanism that leads to displacement of GDP and ultimately to formation of a quaternary complex eIF-2B.eIF-2.GTP.methionyl-tRNA, minimum rate constants have been estimated for the additional reactions assuming in vivo rates of protein synthesis. Rate constants for the other reactions are unexceptional.